DE10554C - Innovations in the representation of luminous gas and in the devices that are used - Google Patents

Description

1879.,

Class 26.

THOMAS FITCH ROWLAND and CHARLES WILLIAM ISBELL

in NEW YORK.

Innovations in the representation of luminous gas and in the ones that are used

Apparatus.

Patented in the German Empire on August 24, 1879 "ib.

The first part of the invention relates to those devices by which the The effect of the hot gases coming from the retorts and that of steam is suspended; the tar vapors which develop during this process are carried along by the gas and converted into luminous gas in a converter. The converter is heated by the lost heat of the retorts in which the gas is evolved.

The second part of the invention relates to those devices by which the generated luminous gas with a lower expenditure of water from its ammonia, Sulfur and carbonic acid content is freed than was previously necessary for this, with ammonia water is obtained from greater concentration.

Fig. Ι is a front view of the gas retorts, the steam scrubber, the converter and the connection between these devices.

Fig. 2 is a basic outline.

Fig. 3 is a cross section along line xx of Fig. I.

Fig. 4 is a cross section through the converter and accessories.

FIGS. 5 and 6 are individual views in transverse and longitudinal section of the emptying opening for the residue in the steam scrubber.

Figures 7 and 8 show the perforated plates of the steam scrubber.

Ä is the retort furnace of common construction for the development of luminous gas with the hydraulic receiver B, from which the gas is discharged through tube C. This pipe C _1, in which the steam jet exhaustor D is switched on, leads at the bottom into the chamber F , so that gas and steam enter the latter. From the upper part of the Dampfscrubbers the gas, the water vapor and the developed Theerdämpfe through pipe G is _from: and led into the converter HI, which is attached to the retort above.

- · From the converter, the gas goes through the pipe K into the cleaning apparatus and on its way to the .Gasometer .. ,, From. From this pipe K a pipe E (see Fig. 3) branches off to the lower part of pipe C in order to form a secondary connection through which the gas is passed directly from C to K if for some reason it does not pass through Steam scrubber should flow. The tube C is provided the pipe K with the Abschlufsventil A ^'1 with the Abschlufsventilen C ¹ C ² C ^3, the pipe with the G Abschlufsventil G \, and is located between the pipes E and C the Abschlufsventil E. ¹ From the lower part of the hydraulic receiver B the pipe J leads the tar into the middle part of the scrubber F. The latter consists of a high cylindrical vessel in which a number of horizontal plates α b, precisely fitted, are inserted. Each plate can consist of several segments for easier insertion into the cylinder, as shown in FIGS. 7 and 8. Of the plates α and b, which alternate in the cylinder, those marked with α are only in the middle part, those marked with b are on the other hand only provided with holes at the edge, so that the gas flowing into the cylinder at C and the steam, which pull upwards together, have to brush the greater part of the surface of the plate, while the tar entering at J and flowing down through the plate holes is also distributed over the greater part of the plates, and thereby comes into intimate contact with the flowing gas and steam. The holes in the plates α and b are conical in order to offer as much surface as possible.

At the bottom of the cylinder is the steam heating pipe c, through which the tar residue that collects here is heated. The heat developed by this heating tube can also be used to convert part of the water, which is contained in the liquid which runs with the tar from the hydraulic receiver, into steam, so that this can serve the same purpose when working without an exhaustor serves as the steam supplied through the exhaustor, namely to facilitate the development of the hydrocarbon vapors from the tar.

At the bottom of the cylinder F is the opening d for the outflow of the tar residues and the con *

. condensation water. Above the cylinder F , the locking box S, FIGS. 5 and 6, is attached, which fills with these residues so that no gas can escape here. At the top of this closure 5 is the overflow opening d \ which communicates with the drainage channel e , which goes into the recess f , from where the drainage pipe g leads to some container.

The heating pipe c also communicates with the depression / into which the condensation water enters. So that the heavy residues can drain off in any case without having to rely on the overflow pipe, an opening h is made near the bottom of the lock box S , which opens into the channel i and communicates with the recess /; the latter is closed by the valve j until it is to be opened. After opening the lid of the box, the valve j can be opened by hand, and the liquid contents of the box and the lower part of the cylinder can thus be drained into the recess f.

The converter can be constructed in different ways; it mainly forms a retort. In order to give it as large a surface as possible on which to cover the retort If the heat is drawn off, it can consist of pipes in the shape of a snake.

The converter shown in FIGS. 1, 2, 3 and 4 simply consists of a U-shaped tube I, which communicates at one end with tube G and at the other end with tube K, and that in an oven-like heating chamber H on top of the retort wall is appropriate. The heating chamber H has a vent at η and a connection at / with the vent channels mm of the retort A , which can be closed off by the slider LL. The direct outlet opening of the flues mm is also provided with slide valves MM . If the converter is to be heated, the slide M is closed and the slide L _{1 is opened} so that all combustion products from the retort fire go around the converter in H and escape at η.

If the conversion of the tar's hydrocarbons into coal gas is to take place using the steam jet exhaustor, the valves C ¹ E ^{1 are} closed and the valves C ² C ³ G ¹ and K \ as well as the valve / ¹ in the connecting pipe J between the hydraulic template and the scrubber open. The gases then go from the hydraulic template i? through pipe C with the steam of the exhaustor into the scrubber, rise here, intimately mixed, through the plate holes, hit the tar distributed on the plates and evaporate from it through the evaporation of naphtha, benzene and other hydrocarbons. The volatile parts of the tar now pass through the converter with the gas and steam, being converted into luminous gas. The entire gas now flows from the converter through scrubbers and cleaning devices and, if necessary, can be subjected to further treatment for use.

If the conversion of the hydrocarbons just described is not to take place during the gas production or if it is necessary to clean or repair the scrubber or converter, both can be done by closing the valves C ¹ C ³ G ¹ and K ¹ and opening the valves C ² and E ^{1 are} switched off.

The gas then goes through pipe C and the steam jet exhaustor D, valve E ¹ and connecting pipe E into the outflow pipe K. Or the gas can be ^{discharged by closing C 2} and E ' as well as C ³ , G ¹ and K ^x and Opening of C ¹ can be conducted directly from the pipe C into the outflow pipe K without flowing through the steam jet exhaustor, scrubber and converter. ^z

Figure 9 is a longitudinal section of the improved scrubber with automatic water distribution apparatus.

Fig. 10 is a longitudinal section,

11 shows a basic outline of the water distribution apparatus.

A is a cylinder made of cast iron or wrought iron of any height, in which the perforated plates or sieves C are mounted horizontally one above the other. The plates or sieves are kept moist by trickling down water, while the gas introduced into the cylinder below through tube D rises and must circulate through and around the plates or sieves. Instead of the perforated plates or sieves, the cylinder A can be filled with brushwood, bushes or similar material. Pipe E leads off the gas at the top, while pipe b leads off the ammonia water at the bottom.

The cylinder A stands in a tower-like building with stairs and galleries through which one can get to all parts of the cylinder and especially to the automatic water-distributing apparatus upstairs in the building; Water flows to the same from pipe ζ .

Under the outlet of the pipe ζ there is a vessel / consisting of two compartments gg , which, suspended between the frames TT , can swing back and forth on the axis h. If a compartment g is full, this side g of the vessel sinks, and the water now runs, as the arrow in Fig. 10 indicates, into the emptied compartment. When a section or side g is lowered, the valve J attached to the bottom opens automatically through its connection to the rod / rotatably attached at m , and the valve closes automatically thanks to the same arrangement when a deflated side g rises. The alternating raising and lowering of the sides g presses the under / rotatable vessel K around its axis further by

the locking cone, which is firmly attached to the vessel, fits into the toothed rim r of the vessel K. In this Gefafs K the water from the lower division flows g through the open valve J pipe means n. The Gefafs / is supported by the pin O, which is in a pivot bearing which forms the center of the K Gefäfses. The vessel / does not rotate about its vertical axis, while the vessel K is rotated gradually about its vertical axis. The vertical shaft z / which carries the vessel K is hollow; it rests in a thrust bearing in the cylinder A. The shaft u is not connected directly to the vessel K , but through the locking sleeve M. Through the channel 5 of an annular cross-section it communicates with the vessel K, so that the water from the latter can flow into this channel S , but must rise again through an inner channel of an annular cross-section in order to be able to flow into the hollow shaft u . The lower part of the shaft u above the thrust bearing is widened to a vessel ν , into the periphery of which the horizontal pipes P, which are provided with drainage holes, can be screwed. The screw-in openings are surrounded by projections y shaped like a trumpet mouth, so that these tubes / can easily be inserted through the closable openings w in the cylinder jacket and removed in the same way for cleaning.

N is a bearing mounted on plate B with a mercury seal for the shaft u. While the water flowing in through ζ causes the vessel / alternately to tip over on the horizontal shaft h to one side or the other, and thereby one or the other section g of their water content the basin K is very energetic, this tipping over of the vessel / causes a step-by-step rotating movement of the basin K, whereby the vertical shaft connected to this basin by the locking sleeve M makes the same movement with the water pipes P and distributes the water regularly in the scrubber.

Claims (6)

Patent Claims: i. The process, various hydrocarbons to convert the tar distilled over from the gas evolution retorts into permanent gas, which process is involved consists that the tar of the combined action of the hot gas from the retorts and is exposed to steam and thereby volatilizing the hydrocarbons, then but the vapors thus produced are carried away with the gas and passed through a converter in which they are Vapors are converted into permanent gas. 2. The combined arrangement of one or more retorts and a steam scrubber, into which the hot gas from the retorts and the tar from the hydraulic receiver occurs, with a converter that is heated by the waste heat from the retorts and which the steam, gas and hydrocarbon vapors enter from the scrubber. 3. The arrangement of the channels or trains with their slides and valves through which the waste heat of the gas evolution retorts is diverted, lim this waste heat either to, through or around the converter in which the conversion of the hydrocarbon vapors in permanent gas, or direct into the atmosphere. 4. In a steam scrubber, the arrangement that the horizontal plates alternate with conical holes in the middle and on the periphery, around the after The tar flowing below is as extensive as possible to the effect of the rising hot ones To expose gases; the tar feed from the template approximately in the middle of the Scrubbers by means of double elbow tubes; the installation of a direct steam heating pipe in the lower part of the scrubber and a hydraulic shutter for the lower part the same viscous product escaping; finally the connection of the template and the scrubber in such a way that the gases from the template either enter the scrubber or directly, avoiding the Scrubbers are derived. 5. On a gas cleaning device (wet scrubber) the attachment of a water distribution device, which is fed by a higher lying water basin and its uppermost part from two on one horizontal axis swaying according to the measure of its filling and alternating on the ground opening and closing vessels, which by their tilting movement the lower part of the water-distributing apparatus with the perforated Set the outlet pipes in a step-by-step rotary motion. 6. In the water distribution apparatus on a Nafs scrubber, make the seal between the the actual apparatus and the distribution pipes through a mercury trap and the establishment of the trumpet-like screw-in openings for the distribution pipes in connection with the closable openings in the scrubber jacket Cleaning the distribution pipes. 1 sheet of drawings.